生物现实和作物模型中的节俭——为什么我们在作物改良中需要两者!

IF 2.6 Q1 AGRONOMY in silico Plants Pub Date : 2019-01-01 DOI:10.1093/insilicoplants/diz010
G. Hammer, C. Messina, A. Wu, M. Cooper
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引用次数: 55

摘要

与统计全基因组预测方法相关的植物育种技术的快速发展有可能增加重大价值,这是作物生理学和建模的新前沿。通过遗传改良提高产量仍然需要基于基因型的表型预测,尽管最近在基因分型和表型方面取得了进展,但这对复杂性状仍然具有挑战性。作物模型能够捕获生理知识,并能可靠地预测基因型-环境-管理(G×E×M)相互作用的表型后果,已被证明有潜力成为一种整合工具。但是,这种生物现实是否具有一定程度的复杂性,从而限制了作物改良的适用性?在利用基因组预测技术的现代育种计划中,需要简单、快速、简洁的模型来处理数千种基因型和环境组合。相比之下,人们通常认为,随着对目标环境中特定性状的基础生物学知识的进步,需要更大的模型复杂性来评估其假定变异的潜力。这种矛盾会导致不同的未来吗?这里有人认为,生物现实和节俭不需要是独立的,也许也不应该是。构建的模型易于允许过程算法在生物水平上的变化,同时使用编码和计算进步来促进高速模拟,可以很好地为支持和加强作物改良技术进步所需的下一代作物模型提供所需的结构。除此之外,科学家之间的跨尺度和跨学科对话被认为至少与模型一样重要,这将需要有效地构建这些模型。
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Biological reality and parsimony in crop models—why we need both in crop improvement!
The potential to add significant value to the rapid advances in plant breeding technologies associated with statistical whole-genome prediction methods is a new frontier for crop physiology and modelling. Yield advance by genetic improvement continues to require prediction of phenotype based on genotype, and this remains challenging for complex traits despite recent advances in genotyping and phenotyping. Crop models that capture physiological knowledge and can robustly predict phenotypic consequences of genotype-by-environment-by-management (G×E×M) interactions have demonstrated potential as an integrating tool. But does this biological reality come with a degree of complexity that restricts applicability in crop improvement? Simple, high-speed, parsimonious models are required for dealing with the thousands of genotypes and environment combinations in modern breeding programs utilizing genomic prediction technologies. In contrast, it is often considered that greater model complexity is needed to evaluate potential of putative variation in specific traits in target environments as knowledge on their underpinning biology advances. Is this a contradiction leading to divergent futures? Here it is argued that biological reality and parsimony do not need to be independent and perhaps should not be. Models structured to readily allow variation in the biological level of process algorithms, while using coding and computational advances to facilitate high-speed simulation, could well provide the structure needed for the next generation of crop models needed to support and enhance advances in crop improvement technologies. Beyond that, the trans-scale and transdisciplinary dialogue among scientists that will be required to construct such models effectively is considered to be at least as important as the models.
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来源期刊
in silico Plants
in silico Plants Agricultural and Biological Sciences-Agronomy and Crop Science
CiteScore
4.70
自引率
9.70%
发文量
21
审稿时长
10 weeks
期刊最新文献
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